WO2012127036A1 - Mechanical watch movement comprising an energy storage element capable of deformation under bending or torsion - Google Patents

Abstract

The invention relates to a mechanical watch movement comprising an energy storage element delivering a torque (100). The energy storage element can deform in a deformation plane under bending and/or torsion and includes: a stationary region or point (20), and a maximum deformation region or point (10), the rotation of the maximum deformation region or point (10) about the stationary region or point (20) being limited to an angle (Θ) of less than 360°. The cross-section (S) of the storage element is variable such that the torque delivered is rendered substantially constant. The energy storage element of the mechanical watch movement supplies the most constant torque possible for the longest time possible.

Description

 Mechanical watch movement comprising a deformable energy accumulator in flexion or torsion

Technical area

The present invention relates to a watch movement

mechanical comprising for mechanical watches, especially for mechanical wristwatches.

State of the art

The barrel of a mechanical watch is an energy accumulator. It comprises a barrel drum, that is to say a cylindrical box closed by a barrel cover and a mainspring, housed in this box.

The known barrel spring is a blade with a generally rectangular section. Before being housed in the drum, it usually has an inverted S shape, as shown in Figure 1A. When it is mounted in the drum T, the barrel spring R is deformed since it is wound around the barrel shaft A which is in the center of the drum T, as illustrated in FIG. 1 B. This process is called

the estrapadage. The free space between the barrel shaft A and the inner radius of the drum T is reserved for the winding and disarming of the barrel spring R. The unwinding of the barrel spring leaf R which seeks to return to its initial shape restores the energy needed to operate a mechanical watch. The toothing of the barrel drum T transmits the torque to the wheel of the watch. Once disarmed, the barrel spring R is expanded against the walls of the drum T, as illustrated in FIG. 1C.

Comparing FIGS. 1A to 1C, it can be seen that the barrel spring R has a point 10 which does not undergo deformations during the strapping. This point corresponds to one of its two ends, in particular that illustrated in Figure 1A. The barrel spring R also has a point 20 which undergoes during deformation the maximum deformation among the deformations undergone by all the points of the barrel spring R. The intensity of this maximum deformation depends on the number of winding turns of the spring barrel R, that is to say the number of turns of the spring barrel during the strapping. This number defines the state of the tension of the barrel spring R and therefore the available torque, measured generally in N · mm.

By indicating with the reference N 'the number of turns of the barrel spring R wound around the barrel shaft A (Figure 1B) and with the reference N "the number of turns of the barrel spring R disarmed and thus relaxed against the walls of the barrel drum T (FIG. 1C), it is possible to define the number N of development of the barrel spring R between these two states according to the following relation:

N = N "- N 'In conventional barrel springs, the number of maximum development revolutions N _max of the barrel spring R belongs to the range 8-10. Thus the rotation of the maximum deformation point 20 around the fixed point 10 is the order of magnitude of about 3000 ° Depending on the number of maximum development revolutions N _max it is possible to optimize the optimal length of the barrel spring R. This number depends on the radius of the shaft A and the drum T , as well as the thickness of the barrel spring R and it is directly proportional to the running time of the watch.

The power reserve of a typical mechanical wristwatch is between 36 hours and 48 hours, sometimes up to a week. The use of complications - chronographs, moon phases, swirls, etc. - leads to an increased need for energy, and therefore a reduction in the power reserve. In order to have a sufficient reserve, known solutions provide for increasing the number of barrels. We therefore know mechanical watches that have a double, triple or even quadruple barrel. The running time of the watches is thus increased arriving up to three, six, eight days, or more. However these multiple barrels occupy a very important part of the volume of the movement.

Another problem with conventional barrel springs is related to the difference in torque provided when the barrel spring is fully tensioned or virtually unwound. The torque provided by a known barrel spring depends on the position of the barrel spring in the barrel drum. There is a torque area corresponding to a small angular range with respect to the mentioned 3000 ° range, in which the watch operates with optimum accuracy. Indeed in this area the torque is constant and adapted to the needs of the train, which corresponds to an optimal accuracy of the watch. Mechanical watches equipped with a torque meter measuring the torque of the barrel spring and making it possible to visualize this zone of torque in which the watch operates with optimum precision are known.

To obtain a more constant torque irrespective of the position of the barrel spring or the level of winding, known solutions use a transmission-rocket-transmission transmission device developed by Leonardo da Vinci: the difference in diameter between the base and the winding level. the top of a conical fuze, around which is wound a chain connected to the barrel spring, functions as a differential compensating for the differences in torque as the barrel spring relaxes. This device thus maintains a substantially constant torque throughout the period covered by the reserve of the watch. However, this mechanism is complex and it is not easy to manufacture it in dimensions adapted to a wristwatch. In addition it requires that precautions are taken, for example a device that blocks the reassembly procedure and thus prevents the chain from breaking.

The document FR66181 1 describes an energy accumulator consisting of several steel strips, elastically flexible and bundled together so that they are applied against each other. other. These slats are fixed together by one of their ends to the frame of the movement. Their free ends are engaged in a terminal loop of a traction chain. During reassembly, the chain is wound on a rocket cam and the lamellae deform in bending. These slats, gradually relaxing, restore their potential energy by driving the cam. The progressive reduction of the tensile force of the slats is compensated by a gradual increase in the lever arm of the application of the force, so that the torque moment is constant. In order to obtain a constant torque the slats therefore require a rocket-chain system, which has the disadvantages mentioned above.

Other known solutions to try to make linear the torque provided by a barrel spring provide a barrel spring locking system, which avoids exploiting his first and last turns. This provides a much more constant energy torque but nevertheless reduces the autonomy of the wristwatch.

Furthermore, in known springs barrels, a significant part of the energy stored during the arming is lost during relaxation due to the friction between the turns of the spring. In order to reduce this friction, the spring is generally lubricated, which poses other problems. Firstly, the lubricant tends to oxidize and become charged with metal particles, so that it should be replaced periodically when servicing the watch. On the other hand, the box of a known barrel drum must be closed by means of a barrel cover which is necessary to contain this lubricant and prevent it from spreading throughout the movement. This box normally has dimensions

important to those of other elements of a wristwatch, and prevents the user from viewing the barrel spring. Its appearance hampers the aesthetics of movement, particularly in the case of a skeleton or transparent watch, and its placement is problematic. There is therefore a need for a mechanical watch movement, in particular a mechanical wristwatch, comprising a energy accumulator which avoids at least one of the limitations of the state of the art mentioned.

Brief summary of the invention

An object of the present invention is to provide a mechanical watch movement, in particular a mechanical wristwatch, comprising an energy accumulator free from the limitations of known barrel springs.

Another object of the present invention is to provide a mechanical watch movement, in particular a mechanical wristwatch, comprising an energy accumulator that can provide a substantially constant torque, that is to say as linear as possible.

Another object of the present invention is to propose a mechanical watch movement, in particular a mechanical wristwatch, comprising an energy accumulator which offers a greater power reserve than the known power reserves.

Another object of the present invention is to provide a mechanical watch movement, in particular a mechanical wristwatch, comprising an energy accumulator that can provide the most constant torque possible as long as possible.

Another object of the present invention is to propose a mechanical watch movement, in particular a mechanical wristwatch, comprising an energy accumulator that can be visible from outside the movement or by the user of a wristwatch skeleton or transparent.

According to the invention, these objects are attained in particular by means of a mechanical watch movement according to claim 1. The mechanical watch movement according to the invention comprises

a energy accumulator providing a torque and deformable in bending and / or torsion comprising

 - a fixed point or region,

 - a point or region of maximum deformation,

 - The rotation of the point or region of maximum deformation is limited around said point or fixed region (20) at an angle (Θ) less than 360 °.

Advantageously, the accumulator has a variable section so as to render the torque restored substantially constant during the restitution, or in any case more constant than if the section were uniform. It is therefore no longer necessary to use a chain-rocket mechanism or other additional mechanism to make the torque constant.

The expression "point or fixed region" in the context of the invention refers to the part of the mechanical watch energy accumulator which does not undergo deformations during the deformation in bending and / or torsion undergone by the accumulator when armed or relaxing. In some embodiments this part may

to correspond to a point, in other cases it can correspond to a region, thus to a set of points.

The expression "point or region of maximum deformation" in the context of the invention designates the part of the mechanical watch energy accumulator which undergoes the maximum deformation, ie the greatest deformation, during deformation in flexion and / or torsion experienced by the accumulator when it is armed or when it relaxes. Again, in some embodiments this part may correspond to a point, in other cases it may correspond to a region, thus to a set of points.

According to the invention, the point or region of maximum deformation is limited in rotation about the fixed point or region by an angle less than 360 °. The point or region of maximum deformation performs therefore a maximum rotation with respect to the point or fixed region

amplitude significantly smaller than the range of about 3000 ° discussed for known barrel springs. This substantially smaller range allows the energy accumulator according to the invention to provide a constant torque without the need to add complex and bulky mechanisms in the movement of the watch.

In a preferred embodiment the accumulator comprises a main direction and orthogonal sections to this main direction whose shape and / or surface are variable. This direction is the direction of longer elongation of the accumulator.

In one variant, the movement comprises means for limiting the point or region of maximum deformation in rotation around the point or fixed region by an angle less than 360 °, for example a disk and a pin which can also be used as a mechanism for

conversion of the deformations of the point or region of maximum deformation into rotations.

In another variant, these means for limiting the point or region of maximum deformation in rotation about the point or fixed region by an angle of less than 360 ° comprise friction mechanisms, for example torque limiting mechanisms comparable to those known in the prior art to avoid breaking the barrel spring during its reassembly.

In order to store a comparable energy or preferably much higher than that stored in barrel springs

Conventional, the energy accumulator is preferably constituted by a deformable mechanical element according to a deformation mode, the rigidity (Young's modulus) according to this mode being significantly greater than that of conventional barrel springs. The reduced amplitude of the compensation is thus more than compensated by the force or the torque necessary to obtain a deformation unit, so that the energy accumulated total is greater than that of conventional barrel springs. This results in an increased power reserve, which can in some embodiments go up to a few weeks or a few months, without substantially increasing the size of the wristwatch.

In addition, the torque provided by the energy accumulator according to the invention is almost constant throughout this period.

In a preferred embodiment, the energy accumulator according to the invention is in the form of a beam. This beam comprises two ends, one end being connected, for example fixed by a recess, the other end being free to deform by bending like a diving board under the action of a force perpendicular to the beam. In this case, the region of maximum deformation is preferably limited in rotation around the fixed region by an angle of less than 20 °, which makes it possible to increase the constancy of the torque throughout the running time of the watch. bracelet.

The lateral section of the beam advantageously has a thickness that is not constant, but varies according to a curve, for example in the form of parabola or exponential: by controlling the shape of this curve it is possible to provide even more torque constant as a function of the angle of rotation of the maximum deformation region.

The shape of this curve is defined numerically, for example using finite element calculation or methods

numerical equation solving mathematics, under the constraint that the torque restored by the energy accumulator is constant. The linearization of the pair in a preferred variant is obtained by calculating topological gradients.

The shape of this curve depends on the material that constitutes the energy accumulator and also its deformation. In a preferred variant, the section of the beam is larger near the point or fixed region than at the point or region of maximum deformation, where the force that allows the accumulator to deform is applied. The torque is calculated relative to the point or fixed region, so the arm substantially corresponds to the length of the beam. Numerical simulations have shown that a lower thickness corresponding to the point of application of the force makes it possible to make the torque constant.

In another variant, the section of the beam is smaller near the fixed point or region than at the point or region of maximum deformation.

In yet another variant, the section of the beam near the point or fixed region is the same as that of the point or region of maximum deformation, but it is larger or smaller than the section at the center of the beam at an intermediate point. between these two ends.

If the accumulator is a beam, in a variant it may have a variable section in a plane perpendicular to the deformation plane of the beam, for example the plane which comprises its main surface. In other words, the section of the beam in this plane may be non-rectangular. For example, the beam may have stops so that, for example, the section of the beam near the center has a larger area than the end section.

In yet another variant the beam has a variable thickness in the deformation plane and also a variable section in the plane of the beam.

In another variant the beam has a constant section with a recess. In a variant, the energy accumulator is designed as a single element having a curved shape with exponential profiles and a washer-shaped section, each washer comprising an annular spring and a beam.

The energy accumulator in all variants of the invention is preferably made of a rigid material, for example steel or iridium or diamond or a titanium alloy or preferably "Gum Metal". The expression "Gum Metal" indicates a type of titanium alloy, in particular the β type, which has a very low Young's modulus and a very high elastic deformation limit σ with respect to those of a known metal.

In a variant, the movement according to the invention comprises a mechanism for converting the deformations of the point or region of maximum deformation of the energy accumulator in rotations, in order to transmit the torque supplied to the work train of the mechanical watch, by determining its operation.

In a variant, the conversion mechanism comprises a pin connected to the accumulator and to a disc or a connecting rod-crank system or a cam or any other mechanism for converting a translational movement into a rotational movement.

In a preferred embodiment, since the value of the torque supplied by the energy accumulator according to the invention is for example of the order of magnitude of 5 N · m, therefore much larger (for example 100 or 1000 times larger ) that the torque provided by a known barrel spring, the movement also comprises a gearbox for converting the rotations obtained by the conversion mechanism into rotations of greater angular velocity to cause the display of the mechanical watch, for example the needles hours, minutes and

possibly seconds. The reduction achieved by this reducer is preferably 2 ⁿ , where n is an integer equal to or greater than six: therefore the angular velocity at the output of the conversion mechanism is increased by at least a factor equal to 64. a reduction ratio in the form of power of 2 makes it possible to produce a gearbox in the form of several successive reduction stages, each stage producing a reduction of a factor of 2.

In a variant this reducer is arranged to be placed through the plate of the movement.

In another independent variant of the invention

the energy accumulator is formed as a ribbon in a tube. Before its insertion into the tube the tape has a substantially helical shape with a diameter of the turns substantially larger than the diameter of the tube. The ribbon is deformed when it enters the tube. In this case the region of maximum deformation is limited in rotation around the fixed region by an angle less than 360 °, which allows the accumulator to provide a substantially constant torque and

to increase the power reserve of the wristwatch.

In a variant, the tube is transparent, to allow the ribbon to be seen from outside the movement or by the user of a skeleton or transparent wristwatch. In a variant

preferential the tube is made of glass or sapphire or Teflon or PTFE (Polytetrafluoroethylene).

In another variant the tube is provided with a cover linked to the region of the ribbon which undergoes the maximum deformation: by turning the lid, it is possible to twist the ribbon.

In another independent variant of the invention

the energy accumulator is in the form of a series of washers placed one against the other, each washer comprising an annular spring and a beam. In a variant the number of washers is between 15 and 25, for example 20. Each washer is deformed around one end of its beam: its annular spring moves in rotation around this end by an angle less than 20 °. The torque is transmitted from one washer to the adjacent one so that the sum of the pairs of all the washers is constant throughout the restitution of energy.

In a variant, the washers all have the same dimensions. In another variant they have dimensions such that the element constituted by this series of washers has a curved shape with exponential profiles. This structure provides a constant torque for a large number of hours. In a variant, each washer is obtained by photolithography.

Brief description of the figures

Examples of implementation of the invention are indicated in the description illustrated by the appended figures in which: Figure 1A illustrates a known S-shaped barrel spring returned before the strapping operation and its mounting in the drum of barrel.

Figure 1B illustrates a known barrel spring wrapped around the barrel shaft. Figure 1C illustrates a known barrel spring relaxed against the walls of the barrel drum.

FIG. 2A illustrates an embodiment of the energy accumulator of the mechanical watch movement according to the invention. FIG. 2B illustrates another embodiment of energy storage of the mechanical watch movement according to the invention.

Figure 3 illustrates another embodiment of

 energy accumulator of the mechanical watch movement according to the invention.

FIGS. 4A and 4B illustrate another embodiment of energy storage of the mechanical watch movement according to the invention.

FIG. 5 illustrates an embodiment of the mechanical watch movement according to the invention.

FIG. 6 illustrates another embodiment of the mechanical watch movement according to the invention.

Example (s) of Embodiments of the Invention

FIG. 2A illustrates an embodiment of the energy accumulator of the mechanical watch movement according to the invention, which is in the form of a beam 1. This beam comprises two ends, one end being fixed, for example linked directly or indirectly to the platen of the movement, the other end 10 being free to deform by bending under the action of a force F perpendicular to the beam, in the manner of a diving board. The beam has a main direction d, visible in Figure 2A. This direction is the direction of longer elongation of the accumulator, in this case the beam. The force is applied in correspondence of the end 10 which corresponds to the region of

maximum deformation. The order of magnitude of the force F to be applied to obtain the maximum deformation is a few Newton. By exerting such a force, the region of maximum deformation 10 moves in rotation around the fixed region 20 by an angle Θ less than 20 °, which allows the accumulator 1 to provide a substantially constant torque along the running time of the watch. The torque is calculated relative to the fixed region 2. The distance between the point of application of the force and the point relative to which the torque is calculated is indicated with the letter b (arm) in Fig. 2A. Force or torque limiting means may be provided in the winding mechanism to prevent the exercise of a force greater than the maximum permitted.

The lateral section of the beam advantageously has a thickness which is not constant, but varies according to a curve, for example in the form of parabola or exponential: this curve makes it possible to provide an even more constant torque as a function of the angle. Θ.

The shape of this curve is defined numerically, for example using finite element calculation or methods

numerical equation solving mathematics, under the constraint that the torque restored by the beam is constant. Torque linearization in a preferred embodiment can be obtained by calculating topological gradients.

The shape of this curve depends on the material that constitutes the energy accumulator and also its deformation.

The area of the orthogonal sections S 'at the main direction d is also variable.

In another variant the shape of the orthogonal sections S 'to the main direction d can also be variable.

In the variant illustrated in FIG. 2A, the section of the beam is larger in proximity to the fixed region 20 than with respect to the region of maximum deformation 10. Numerical simulations have demonstrated that a lower thickness in correspondence of the point of application of the force F makes it possible to linearize the calculated torque by considering as the center the fixed region 20.

In a variant illustrated in Figure 2B, the beam 1 has a variable section S 'in a plane perpendicular to the deformation plane of the beam, for example in the plane which comprises its main surface. The area of the orthogonal sections S 'at the main direction d is also variable. In another variant the shape of the orthogonal sections S 'to the main direction d can also be variable. In other words, the section of the beam is not necessarily rectangular and does not always have the same dimensions. In the example shown the beam present in

correspondence of its lateral surfaces of the abutments so that the section of the beam in correspondence of its center has a surface greater than the surface of its section in correspondence of its fixed region and / or its maximum deformation region.

Figure 3 illustrates another embodiment of

the energy accumulator of the mechanical watch movement according to an aspect according to the invention, in the form of a ribbon 3 in a tube 4. Before its insertion into the tube, the ribbon 3 is preformed so as to have the rest a substantially helical shape with a diameter of turns substantially larger than the diameter d of the tube. The ribbon 3 is thus deformed when it is introduced into the tube 3.

In this embodiment, the maximum deformation region 10 performs during the winding a rotation around the fixed region 20 by a maximum angle Θ less than 360 °, which allows the accumulator to provide a substantially constant torque .

In a variant, the tube 4 is transparent, to allow the ribbon 3 to be seen from outside the movement. In a preferred embodiment, the tube 3 is made of glass or sapphire or Teflon or PTFE (Polytetrafluoroethylene). In another variant the tube 4 is provided with a cover 40 connected to the region 10 of the ribbon 3 which undergoes the maximum deformation: by turning the lid 40, it is thus possible to twist the ribbon 3. In a variant, when unwinding, the ribbon 3 rotates the lid, which transmits a rotational movement to the other gears of the movement.

In another variant the tube 4 is not provided with a lid and during its unwinding, the ribbon 3 exits the tube 4 with a roto-translation movement which must therefore be converted into a rotational movement.

As illustrated in FIG. 4A, in another variant, the energy accumulator of the mechanical watch movement according to another independent aspect of the invention is made in the form of an element 50 constituted by a series of washers 5 placed one against the other. An exemplary embodiment of a washer 5 is illustrated in Figure 4B. It comprises an annular spring and a beam. In a variant the number of washers is between 15 and 25, for example 20. Each washer is deformed around an end E of its beam: the region of maximum deformation 20 is therefore constituted by the annular spring 20 and the fixed point by the end E of the beam. The annular spring therefore rotates around this end E by an angle Θ less than 20 °. The torque is transmitted by a washer to the adjacent one so that the sum of the pairs of all the washers is linear.

In a variant, the washers 5 all have the same dimensions. In another variant they have dimensions such that the element 50 constituted by this series of washers 5 has a curved shape with exponential P profiles. This structure provides a constant torque for about 100 hours. In a variant, each washer 5 is obtained by photolithography. In another variant, the energy accumulator is made in the form of a single element 50 having a curved shape with exponential profiles and a washer-shaped section 5.

The energy accumulator according to all embodiments is made of a rigid material, for example steel or iridium or diamond or a titanium alloy or "Gum Metal". The energy accumulator may be of crystalline or amorphous material.

The use of "Gum Metal" allows the accumulator to have a very low Young's modulus and an elastic deformation limit σ very high compared to those made in a known metal.

Figure 5 schematically illustrates an embodiment of the mechanical watch movement.

In a variant, the movement according to the invention comprises a mechanism 200 for converting the deformations of the point or region of maximum deformation of the energy accumulator 100 in rotations, in order to transmit the torque supplied to the wheelwork 400 of the watch.

mechanical.

In a variant conversion mechanism 200 comprises a pin connected to the accumulator and to a disc or a crank-handle system or a cam or any other mechanism for converting a translational movement into a rotational movement.

In a preferred embodiment, since the value of the torque supplied by the energy accumulator according to the invention is of the order of magnitude of 5 N · m, therefore of several orders of magnitude (for example about 1000 times larger) greater than the torque provided by a known barrel spring, the movement also comprises a gearbox 300 for converting the rotations obtained by the conversion mechanism into rotations of angular speed greater to cause the display of the mechanical watch, for example the hour hands, minutes and possibly seconds.

The reduction achieved by this reducer 300 is of the order of magnitude of 2 ⁿ , n being an integer equal to or greater than six: therefore the angular velocity at the output of the conversion mechanism is increased by at least a factor equal to 64.

In a variant this reducer 300 is arranged to be placed through the plate of the movement, which has for this purpose a hole for its location. The thickness of this reducer is greater than that of the plate.

Figure 6 schematically illustrates an embodiment of the mechanical watch movement. The energy accumulator, made in the form of a beam 1 of rectangular section, deforms under the action of a force not shown. The deformed beam is represented with dotted lines. The point of maximum deformation 10 is thus rotated by an angle Θ around the fixed point 20.

In correspondence with the point of maximum deformation 10, a pin G makes it possible to bind the beam 1 to a disk D. The pin G and the disk D are an exemplary embodiment of the means for limiting the point of maximum deformation in rotation around fixed point 20 of an angle Θ less than 360 °, for example 20 °. Indeed the beam Y deformation would break for angles Θ larger.

In this case, the pin G and the disk D also make it possible to convert the deformations of the point of maximum deformation 10 into rotations. A gearbox 300, partially illustrated and comprising wheels which share the same axis 1000 of the disk D to convert the rotations angular speed rotations greater in order to cause for example the display of the mechanical watch.

In another variant these means for limiting the point or region of maximum deformation in rotation about the point or fixed region 20 by an angle Θ less than 360 ° comprise torque limiting mechanisms, for example friction mechanisms in the winding crown or in the winding system, comparable to the torque limiting mechanisms known in the prior art to avoid breaking the barrel spring during its reassembly.

Reference numbers used in the figures

1 Beam

 Y Deformed beam

 3 Ribbon

 4 Tube

 5 Washer

 10 Point or region of maximum deformation

 10 'Point or region of deformed maximum deformation

 20 Fixed point or region

 40 Lid or cap of tube 4

 50 Set of washers 5

 100 Energy accumulator

 200 Conversion Mechanism

 300 Reducer

 400 Clockwork of a mechanical watch

 1000 Axis of the D disk

 R Barrel spring

 T Drum drum

 A barrel shaft

 No. of revolutions of the barrel spring R wound around the barrel shaft A

 No. of revolutions of the barrel spring R expanded against the walls of the barrel drum T

 Θ Angle of rotation

 F Force on the beam 1

 S Section of the beam 1 in the deformation plane of the beam d Tube diameter 4

 P Profile of washers 50

 E End of the beam of the washer 5

 G Pin

 D Disk

d Main direction

 S 'Section of the beam 1 orthogonal to the main direction d k Distance between the point of application of the force F and the point or fixed region 20

Claims

claims

1. Mechanical watch movement comprising

 a energy accumulator restoring a torque (100) and deformable in bending and / or torsion comprising

 a point or a fixed region (20),

 a point or region of maximum deformation (10),

the rotation of said point or region of maximum deformation (10) being limited around said fixed point or region (20) at an angle (Θ) of less than 360 °

 said accumulator having a section (S) variable so as to render the restituted torque substantially constant.

2. The movement according to claim 1, said energy accumulator is in the form of a beam and has a said section (S) in the deformation plane of variable thickness so as to render the restituted torque substantially constant as a function of said deformation.

3. The movement according to one of claims 1 or 2, said accumulator having a main direction (d), and orthogonal sections (S ') to this main direction whose shape and / or surface are variable.

4. The movement of claim 1, in the form of an element (50) having exponential profiles (P) and a washer-shaped section (5), said washer (5) comprising an annular spring and a beam.

5. The movement according to one of claims 1 to 4, said energy accumulator being made of Gum metal.

6. The movement according to one of claims 1 to 5, comprising a conversion mechanism (200) of the deformations of said point or region of maximum deformation (10) of said energy accumulator (100) in rotations.

7. The movement according to one of claims 1 to 6, said conversion mechanism (200) comprising a pin (G) and a disk (D) and / or a connecting rod-crank system and / or a cam.

8. The movement of claim 7, comprising means for limiting said point or region of maximum deformation (10) in rotation, said means comprising said pin (G) and said disk (D).

The movement according to one of claims 1 to 8, comprising a display and a gearbox (300) for converting said rotations into larger angular velocity rotations to drive said display of said watch.

10. The movement according to claim 9, the reduction of said gear (300) being of the order of magnitude of 2 ^Λ η, n being an integer equal to or greater than 6.

1. The movement according to one of claims 9 to 10, said gear (300) being arranged to be placed through the platen of said movement.

12. A method of manufacturing an energy accumulator (100) for deformable mechanical movement in bending and / or torsion comprising

 a point or a fixed region (20),

 a point or region of maximum deformation (10),

the rotation of said point or region of maximum deformation (10) being limited around said fixed point or region (20) at an angle (Θ) of less than 360 °

including the next step - Digitally defining a section (S) variable so as to render the restituted torque substantially constant.

The method of claim 12, said definition comprising calculating topological gradients.